FI89566C - Process and apparatus for processing stone - Google Patents

Abstract

A procedure, and a means, for machining stone to globular shape. In the procedure, in a stone blank (1) is machined a plurality of mutually spaced slots (2) with the shape of a circular arc, of which the bottoms (3) are substantially on the level of the surface of the globe which is being produced, the portions of the stone blank between the slots are removed, the stone blank, substantially round-shaped, is ground to become round, and the region of the supporting point of the stone blank, which has remained untreated, is machined down to the level of the rest of the spherical surface. <IMAGE>

Description

1 89566

METHOD AND APPARATUS FOR STONE WORKING

The invention relates to both a method and a device for processing a stone into a spherical shape. The invention 5 is particularly directed to the production of large spheres from stone, the sphere having a diameter of between 0.5 and 3, preferably 1 to 2 m.

It is relatively easy to make small round-shaped pieces of the order of ten centimeters in diameter, even from hard stones. The parts can be turned in different ways or a machining blade, such as a hole drill, can be used.

increasing the diameter of the ball to be prepared for more than half a meter, however, problems arise, since the blank 15 to press the relatively much, whereby its handling is difficult, and its fixing and rotating a conventional turning machine almost impossible. In addition, the large amount of stones to be machined causes problems.

The prior art in the field of the invention is disclosed in German application DE-3723764. It is known from this publication to process a sphere from stone, but the method presented in it cannot make very large and heavy spheres because the stone grind is rotated about its horizontal axis and also around its vertical axis, causing large forces on the stone blank support points, resulting in too expensive and heavy support structures.

One known way to make large pieces of stone from hard stone materials is to use a perforated plate. 30 In this case, a large plate with a round hole, the edges of which are provided with cutting diamonds, is rotated and turned around a circular multifaceted sawn stone blank so that a flat and round ball is finally formed. Such machining is cumbersome 35 and slow and, above all, very expensive, as large diamond perforated plates cost tens of thousands of marks a piece. Similarly, a disadvantage of the prior art is that each ball size to be manufactured must have its own perforated plates, whereby the blades precisely delimit the ball sizes that can be produced. Thus, it is not necessarily possible to make the stone blank the largest possible ball, but only the largest ball obtained from the stone by the range of blades, whereby the amount of stone to be processed from the stone blank can increase significantly, increasing processing time and manufacturing costs.

The object of the invention is to eliminate the above-mentioned drawbacks. In particular, the object of the invention is to provide a novel method and device by means of which the largest possible ball can be machined from various large and massive boulders with simple and inexpensive tools.

15 As regards the features characteristic of the invention, reference is made to the claims.

In the method according to the invention for machining a stone into a spherical stone blank, a number of circular arcuate grooves 20 are machined at a distance from each other, the bottoms are substantially flush with the resulting ball, the parts between the grooves are removed, the substantially circular stone blank is ground.

According to the invention, the machining of the grooves and the grinding of the surface are performed by a machining blade running along a rigid circular support arc around the blank, the blank resting on the blank support and rotating the blank and the support arch 30 about a vertical axis relative to each other.

Preferably, the area of the fulcrum is machined round in a manner similar to the rest of the spherical surface, i.e. first grooves are machined into it, the ridges between the grooves are knocked off and then the area is ground smoothly. It is also, of course, possible that, after grinding, the spherical surface is polished to a suitable gloss.

In one embodiment of the invention, the stone blank 3 39566 is supported only from below, whereby the circular arcs to be machined may be more than 300 ° from the vicinity of the support point around the stone blank to the other side of the support point.

It is also possible that the stone blank is supported on 5 opposite sides, i.e. below and above, whereby the machining takes place in a circular arc of less than 180 ° from the vicinity of the second support point to the vicinity of the second support point.

In the method according to the invention, the machine tool 10 may be stationary and the stone blank is rotated by a suitable power device, or the stone blank may be held in place, whereby the surrounding machine tool rotates around the stone blank.

Since the grooves to be machined in the vicinity of the support points become relatively close to each other or even converge, the length of the grooves to be machined can also be varied so that, for example, every other groove is machined as far as possible in the vicinity of the support point or support points. thus saving machining time and blades. The distances between the grooves as well as the making of the deficient grooves described above can vary according to the hardness of the stone to be machined, so that the leaves between the grooves can always be properly broken off from the stone blank.

The stone processing device according to the invention comprises a support frame on which a support arc in the shape of a circular arc rests. The support arch has a blade carriage that can be moved along it, to which the Machining Blades are attached. In addition, the device 30 includes a blank support supported on a support frame, on which the stone blank to be machined is supported.

Preferably, the height of the blank support is adjustable so that the stone blank can always be placed as precisely as possible at the center of curvature 35 of the support arc so that the largest possible sphere can be machined from the stone blank. The blank support may be a hydraulic cylinder or other piston-like member which can be securely locked to the desired height in one way or another.

In one embodiment of the invention, the support arch is an arc of a circle of about 180 °, the upper end of which includes an upper support supported on a stone blank. In this case, the stone blank is supported on opposite sides by a support arc, and the stone blank and the support arch are rotatable relative to each other about a vertical axis defined by the blank support and the upper support.

It is also possible that the support arch is a circular ring around the stone blank, in which case the stone blank can be supported either only on the blank support or also on the top support. If the stone blank is based only on the blank support, the workpiece can be machined more than 300 ° around the arc of the stone blank. It is also noteworthy that in order to speed up the machining, it is possible to use two or more blade carriages and blades in the support arc at the same time, whereby the machining speed increases correspondingly.

An advantage of the method and device 20 according to the invention over the prior art is that large spheres can be made of stone by means of the invention without special tools and blades, because grooving can be done with standard diamond blades and surface grinding smooth with other conventional blades such as an annular blade rotated and moving the ball against the sheath. Thus, with the method and device according to the invention, the machining blade costs of large spheres made of hard stone materials are obtained at a fraction of the current ones.

The invention will now be described in detail with reference to the accompanying drawing, in which Figure 1 schematically shows a device according to the invention, Figure 2 schematically shows another device according to the invention and Figure 3 shows a partially machined stone blank.

The device 5 89566 according to the embodiment of Fig. 1 comprises a support frame 7 on which a blank support 11 and a support arch 8 rest. The support arch 8 extends in a circular arc to the other side of the stone blank 1 to be machined, i.e. above, where it rests on the top surface 5.

The blank support 11 is formed by a piston-like, height-adjustable and lockable in place pin, on which the stone blank 1 is supported substantially in the middle. The upper support 12 is formed, for example, by a hydraulic or pneumatic cylinder-10 blade and a piston, which is pressed against the upper surface of the stone blank. Thus, the upper support and the blank support together form a vertical axis around which the stone blank can be rotated or around which the device around the stone blank can be rotated.

The semicircular arc-shaped support arch 8 comprises a blade carriage 10 which, by means of a suitable power device, can be moved along the support arch from its end to the end. A blade disc 6 or other suitable machining blade is attached to the blade carriage 10 depending on the machining to be performed. The position of the blade carriage 10 on the support arc 8 in the radial direction of the arc can always be adjusted according to the size of the ball to be machined from the stone blank 1. In addition, the device comprises a power device 13 by means of which the support arch 8 can be turned about a vertical axis with respect to the stone blank 1 or the stone blank 1 can be turned about a vertical axis with respect to the support arch 8.

Figure 2 shows another embodiment of the invention. It otherwise corresponds to the device of Figure 1, but the stone blank 1 is not supported above it on a support arch and the support arch 9 is formed by a circular perimeter. In this case, the blade carriage 10 can be moved along the support arch 9 from the vicinity of the blank support 11 by more than 300 ° to the vicinity of the blank support on one side thereof. Also in this application, alternatively, either the stone blank 1 can be turned 35 with respect to the support arch 9 or the support arch 9 can be turned with respect to the stone blank 1 about a vertical axis.

The devices 6 39566 according to the invention shown in the drawing are used as follows. The stone blank 1 is raised and supported substantially in the middle on the blank support 11 and is raised to such a height that the center of the ball to be machined from the stone blank comes to the center of curvature of the support arch 8 or 95.

By examining the stone blank, it can be decided how large a ball can be made of it or, if desired, a ball of a certain size, the blade carriage 10 is adjusted to a suitable position in the radial direction of the support arc and a diamond blade disc 6 is attached, then the blade 1 is sawn into adjacent grooves 2 so that the groove bottoms 3 pass the task on the surface of the ball. The grooves are machined by moving the blade carriage 10 the entire distance allowed by the support arc while the blade blade cuts into a stone blank with a circular groove of 15 to 15 feet. After the cut, either the support arch or the stone blank is turned depending on the size of the stone blank, e.g. 5 - 10 °, and a new cut is made. In this way, the entire stone blank is circumferentially formed into leaf-like portions 4 between the grooves, which can be removed by wedging, hammering or otherwise striking, after which the stone blank becomes a roughly circular body.

A suitable grinding tool is then attached to the blade carriage 10, for example an annular diamond-25 blade, the entire diamond blade ring, e.g. 10 to 30 cm in diameter, being fitted against the surface of the stone.

Thereafter, by rotating the grinding wheel, conveying the blade carriage 10 along the support arc and turning the stone blank 1 and the support arc relative to each other 30, the entire casing of the round stone is ground.

The ground round stone is then lifted from the blank support 11 and an annular or cup-shaped support is placed on the blank support and the round stone is turned so that the ground round part of the ball shell 35 enters the cup support. In this position, the ball is arranged at its original machining height or the size of the cup-shaped support stipulates that the ball is automatically maintained at its machining height. Next, the areas of the support points 5 left in the machining of the ball, 1 or 2 depending on the application, are machined into a circular spherical surface in a corresponding manner. Of course, it is possible / 5 that if there is relatively little machining in the areas of the support points, they can be sanded directly without rough machining with a blade.

Once the sphere has been ground to the exact shape of a sphere, it can be polished to a gloss 10 by conventional polishing means with a polishing tool attached to the blade carriage 10.

The invention has been described above by way of example with the aid of the accompanying drawings, however, various embodiments of the invention are possible within the scope of the inventive idea defined by the claims.

Claims (10)

A method of machining a stone into a spherical shape, in which a plurality of circular arcuate grooves (2) are machined into the stone blank (1), the bottoms (3) of which are substantially flush with the surface of the resulting sphere, a substantially circular stone blank is ground round and - the untreated stone blank support point area (5) is machined flush with the rest of the spherical surface, characterized in that the grooves (2) are machined and the surface ground the blank resting on the blank support and rotating the blank and the support arc resting on the blank support about a vertical axis relative to each other. Method according to Claim 1, characterized in that the region (5) of the fulcrum is machined into a circle in a manner similar to the rest of the spherical surface. A method according to claim 1, characterized in that the stone blank (1) is supported during machining only from below, wherein the circular arcs to be machined are more than 300 degrees from the proximity of the support point around the stone blank to the other side of the support point. Method according to Claim 1, characterized in that the stone blank (1) is supported on opposite sides, the machining taking place in a circular arc of less than 180 degrees from the vicinity of the support point to the vicinity of another support point. Method according to one of Claims 1 to 4, characterized in that the grooves (2) are sawn with a blade blade (6) by rotating the stone blank (1) and 9 39566 machine tools stepwise relative to one another. Method according to one of Claims 1 to 5, characterized in that the region (5) of the support point of the stone blank (1) is removed by turning it to a machining position in which the position of the center point of the stone blank remains unchanged. A device for processing a stone into a spherical shape, characterized in that the device comprises a support frame (7), a circular arc-shaped support arch (8,9), a blade carriage (10) movable along the support arc, to which the machining blades can be attached, and a blank support (11) supported on the support frame. the workpiece stone blank (1) is supported to rotate about a vertical axis with respect to the support arc. Device according to Claim 7, characterized in that the blank support (11) is height-adjustable for placing the stone blank (1) at the center of curvature of the support arch (8, 9). 8 89566 Device according to Claim 7 or 8, characterized in that the support arch (8) is a 180-degree circular arc, the upper end of which comprises an upper support (12) resting on the stone blank (1) so that the stone blank and the support arch are rotatable relative to each other. around the vertical axis defined by the grinding support and the upper support. Device according to one of Claims 7 to 9, characterized in that the blank support is provided with an annular or cup-shaped intermediate support, on which the sphere 30, which is not machined in the region of the support point, can be supported without changing its center position with respect to the support arc. ίο 89566